KR20100105451A - Data transmission method in wireless communication system including relays - Google Patents

Abstract

PURPOSE: A method for transmitting data in a wireless communication system including a relay is provided to determine frame configuration and transmission timing of a backhaul downlink and a backhaul uplink in consideration of at least one of transceiving switching time and signal transmitting time to transceive data, thereby effectively transceiving data between the relay and the base station in the wireless communication system. CONSTITUTION: A base station transmits a backhaul downlink signal according to frame configuration of backhaul downlink and timing of the backhaul downlink determined in consideration of at least one of transceiving switching time and signal transmitting time of a relay station. The relay receives the backhaul downlink signal according to the frame configuration of the backhaul downlink and the timing.

Description

Technical Field [0001] The present invention relates to a data transmission method for a wireless communication system including a relay,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to data transmission / reception in a wireless communication system, and relates to data transmission / reception between a relay and a base station in a wireless communication system in which a relay exists.

A Relay Station (RS) acts as an intermediary between a base station and a user equipment (UE). As shown in FIG. 1A, a relay station (BS) The main purpose is to install a relay at the boundary to effectively expand the cell coverage and increase the throughput.

Figure 1a shows a relay usage model that can achieve coverage extension using a relay. That is, the relay may provide services to the UEs located outside the cell radius of the donor base station or outside the cell coverage boundary of the donor base station, or between terminals located opposite to the base station facing the building forest, , Terminals located in buildings with poor wireless environment, and relays relaying signals of base stations for terminals in the subway.

Figure 1B shows a relay usage model that improves cell throughput using relays. The relays 200-1 and 200-2 shown in FIG. 1B are located within the cell radius of the donor base station 100 and provide better quality of service than those without relays for terminals located near the cell boundary. That is, in the case of the terminal 1 (300-1) in the case where there is no relay with the base station, although a low transmission rate, for example, a QPSK link is provided, the terminal 2 (300-2) In the case of the terminal 3 (300-3), the relay can convert the data received from the base station to a high transmission rate such as 64QAM and transmit the data, thereby improving cell throughput.

Relay technology can be used to transmit data between a base station and a user terminal in various forms. For example, the base station transmits data directly to the user terminal without the relay, and the relay node exists between the base station and the user terminal and relays the data. This type of relaying increases the existing cell coverage Improves throughput. Another type is a case where another user terminal performs relay transmission between a base station and a terminal, and autonomous ad-hoc network configuration and management are required. This type of transmission is suitable to support an emergency call that can be replaced if communication is not possible with the existing network.

Although the definition of two links between a base station and a terminal is sufficient in the past, the introduction of such a relay function in a wireless communication network has shown that a wireless link to be added by adding a relay . That is, uplink and downlink between the donor base station and the relay, uplink and downlink between the relay and the terminal have to be additionally considered.

Although much research has been actively conducted through the standardization organizations such as LTE-Advanced and IEEE 802.16m of 3GPP in relation to relay technology to date, there are still many studies on data transmission and reception between relays and base stations, Channel transmission method and the like are not presented, and the necessity of this is increasing.

An object of the present invention is to provide a procedure for data transmission / reception between a relay and a base station, a channel configuration, and a channel transmission method in a wireless communication system.

According to another aspect of the present invention, there is provided a method of downlink transmission in a mobile communication network including a relay, the method comprising the steps of: And transmitting a backhaul downlink signal according to a backhaul downlink timing and a frame structure of the backhaul downlink determined in consideration of at least one of signal transmission time and signal transmission time of the backhaul downlink, And receiving a signal.

Wherein the step of transmitting the backhaul downlink signal comprises the steps of: removing the symbols from the first symbol of the base station access downlink subframe (the number of symbols to which the relay access downlink control channel is transmitted + 1) The backhaul downlink signal can be transmitted using the symbols for transmitting the backhaul downlink signal including the symbols starting from the last symbol to the last symbol. At this time, the starting point of the relay access downlink subframe related to the timing of the backhaul downlink is set backward by the length of the downlink backward guard interval from the time when the first symbol of the base station access downlink subframe starts to be received by the relay .

Wherein the step of transmitting the backhaul downlink signal further includes the steps of excluding symbols corresponding to the number of symbols to which the relay access downlink control channel is transmitted from the first symbol of the base station access downlink subframe, The backhaul downlink signal can be transmitted using the symbols for transmitting the backhaul downlink signal having the maximum value up to the previous symbol except for the symbol.

At this time, the starting point of the relay access downlink sub-frame related to the timing of the backhaul downlink is the time when the control information for the relay access downlink is transmitted from the time when the first symbol of the base station access downlink sub- And the length of the downlink pre-guard interval.

In order to match the start time of the relay access downlink subframe to the start time of the base station access downlink subframe, the transmission time of the relay access downlink subframe is set such that the first symbol of the base station access downlink subframe starts to be received by the relay From the time point, it is set forward by half the time indicated by the timing advance information transmitted by the base station to the relay.

The step of transmitting the backhaul downlink signal further includes the steps of: removing symbols corresponding to the number of symbols to which the relay access downlink control channel is transmitted from the first symbol of the base station access downlink subframe; The backhaul downlink signal can be transmitted using the symbols for transmitting the backhaul downlink signal. At this time, it is preferable that the starting point of the relay access downlink subframe related to the timing of the backhaul downlink is set to a time point at which the first symbol of the base station access downlink subframe starts to be received by the relay.

The downlink transmission method may further include the step of the relay transmitting the relay access downlink subframe to the relay terminal according to the frame configuration and timing of the backhaul downlink.

The frame configuration and timing of the backhaul downlink are controlled by a time interval in which control information for downlink relay access downlink from a relay to a relay terminal is transmitted and control for a downlink base station access downlink from a base station to a base station terminal May be determined by further considering at least one of time intervals in which information is transmitted.

Meanwhile, the downlink transmission method may further include transmitting information on the transmission / reception switching time of the relay to the base station before the downlink transmission step.

The information on the transmission / reception switching time is preferably transmitted through higher layer signaling, particularly RRC signaling.

According to another aspect of the present invention, there is provided an uplink transmission method for a mobile communication network including a relay, the relay including a relay transmission / reception switching time, Transmitting a backhaul uplink signal according to a frame structure and timing of a backhaul uplink determined in consideration of at least one of signal transmission time and signal transmission time and receiving a backhaul uplink signal according to a frame configuration and timing of the backhaul uplink; .

The step of transmitting the backhaul uplink signal may include transmitting a backhaul uplink signal using symbols for transmitting a backhaul uplink signal including a first symbol starting from a second symbol of a backhaul uplink subframe to a last symbol. At this time, it is preferable that the starting point of the backhaul uplink sub-frame related to the timing of the backhaul uplink is set backward by the uplink guard interval at the time when the relay transmits the base station access uplink signal in the terminal mode of the relay.

The step of transmitting the backhaul uplink signal may also transmit the backhaul uplink signal using symbols for transmitting a backhaul uplink signal, the first to the second symbol starting from the first symbol of the backhaul uplink subframe. Here, it is preferable that the starting point of the backhaul uplink sub-frame related to the timing of the backhaul uplink is set backward by an uplink guard interval at the time when the relay transmits the base station access uplink signal in the terminal mode of the relay.

The transmitting of the backhaul uplink signal may further include transmitting a backhaul uplink signal using symbols for transmitting a backhaul uplink signal having a maximum value of symbols starting from a second symbol of the backhaul uplink subframe to a last symbol And the start symbol and the end symbol of the symbols for transmitting the backhaul uplink signal may vary according to at least one of a length of the signal transmission time of the backhaul uplink and a transmission / reception switching time of the relay. At this time, it is preferable that the start time of the backhaul uplink subframe in relation to the timing of the backhaul uplink is set to be equal to the start time of the base station access uplink subframe. The starting point of the backhaul uplink sub-frame related to the timing of the backhaul uplink is also a time point at which the base station access uplink signal is transmitted in the terminal mode of the relay, Can be set back to about half.

The step of transmitting the backhaul uplink signal may further include transmitting backhaul uplink signals using symbols for transmitting a backhaul uplink signal including symbols starting from a first symbol of a backhaul uplink subframe to a last symbol have. Here, the start time of the backhaul uplink sub-frame related to the timing of the backhaul uplink is preferably set to a time when the relay transmits the base station access uplink signal in the terminal mode of the relay.

A relay apparatus according to another aspect of the present invention performs transmission and reception with a base station through a backhaul link, notifies the base station of information on a time required for transmission and reception switching, Receives the backhaul downlink signal from the base station according to the frame structure and timing of the link, and transmits the backhaul uplink signal to the base station according to the frame structure and timing of the backhaul uplink determined in consideration of the time required for the transmission / reception switching.

A base station according to another aspect of the present invention includes: a base station for communicating with at least one relay through a backhaul link, the frame structure of a backhaul downlink determined in consideration of at least one of a transmission / And transmits the backhaul downlink signal according to the timing.

A downlink transmission method according to another aspect of the present invention includes a step in which a base station selects at least one interval configuration information among interval configuration information of a predetermined plurality of backhaul link signals and transmits the selected interval configuration information to a relay, Information on symbols for which a signal is actually transmitted among the entire BS access downlink subframes, information on downlink transmission timing of the corresponding relay subframe, and information on symbols through which signals are transmitted in the entire backhaul uplink subframe And information regarding the backhaul uplink transmission of the relay and the backhaul uplink reception timing of the base station.

According to another aspect of the present invention, there is provided an uplink transmission method for a mobile communication network including a relay, In the case where two or more uplink subframes are consecutively arranged, a guard interval located at a position where one of the backhaul uplink subframes touches another backhaul uplink subframe is replaced with a backhaul uplink signal interval, Constructing an uplink subframe and performing a backhaul uplink transmission using the configured uplink frame.

The uplink transmission method includes a step in which a base station receives two or more consecutive backhaul uplink subframes from a relay and a step in which the base station acquires at least two consecutive backhaul uplink subframes from a predetermined independent backhaul uplink subframe type, And deriving the shape of the subframe.

The type of independent backhaul uplink subframe used by the relay may be fixed or predefined.

The uplink transmission method may further include a step of the base station transmitting information on the type of the independent backhaul uplink subframe to be used by the relay to the relay in advance and the independent backhaul uplink The information on the type of the subframe may be information on the selected subframe type among at least one backhaul uplink subframe type set in advance between the relay and the relay.

In addition, information on the selected sub-frame type may be transmitted through upper layer signaling.

The step of configuring the uplink frame may constitute an uplink frame in which the first backhaul uplink demodulation reference signal and the second backhaul uplink demodulation reference signal are arranged in one backhaul uplink subframe.

The first backhaul uplink demodulation reference signal and the second backhaul uplink demodulation reference signal are transmitted through a predetermined number of symbols (one half of the maximum number of symbols included in one backhaul uplink subframe - 1) Can be located.

The forming of the uplink frame may comprise configuring an uplink frame in which only one backhaul uplink demodulation reference signal is arranged in one backhaul uplink subframe.

The backhaul uplink demodulation reference signal is generated by multiplying the backhaul uplink demodulation reference signal in a single backhaul uplink subframe by the difference between the number of preceding symbols in time and the number of following symbols in time, Is not disposed.

According to another aspect of the present invention, there is provided a relay apparatus for relaying uplink data of a backhaul uplink subframe to be transmitted to a base station, A guard interval located at a position where a subframe is in contact with another backhaul uplink subframe is replaced with a backhaul uplink signal interval to adaptively construct a backhaul uplink subframe and a backhaul uplink transmission using the configured uplink frame .

In accordance with another aspect of the present invention, a base station, when receiving two or more consecutive backhaul uplink subframes from a relay, is configured to extract, from the form of independent backhaul uplink subframes, Shape.

According to another aspect of the present invention, there is provided a backhaul downlink transmission method including: transmitting a relay access downlink control channel including a number of symbols through which a relay access downlink control channel is transmitted, Determining a transmission start point of the backhaul downlink signal in consideration of the number of the backhaul downlink signals, and transmitting the backhaul downlink signals to the relay according to the transmission start time of the determined backhaul downlink signal.

The backhaul downlink transmission method may further include notifying, to the base station, the number of symbols to which the relay transmits the relay access downlink control channel, before the determination of the transmission start time of the backhaul downlink signal.

The base station may further include a step of previously transmitting information on the number of symbols to which the relay access downlink physical control channel is transmitted among the relay access downlink signals to the relay before transmission of the relay access downlink physical control channel have.

The backhaul downlink signal may be transmitted through a backhaul downlink physical control channel and a backhaul downlink physical data channel and the backhaul downlink physical data channel may include a portion of a region allocated in advance as a backhaul downlink physical control channel .

The backhaul downlink physical control channel includes information indicating whether the backhaul downlink physical data channel includes a part of an area allocated to the backhaul downlink physical control channel.

Relay system information, which is commonly applied to all relays in cooperation with the base station, is transmitted through a relay common backhaul downlink physical control channel which is a part of a backhaul downlink physical control channel.

The relay system information can be changed according to the relay system information change period and is not changed within one relay system information change period.

The relay common backhaul downlink physical control channel includes a notification as to whether the relay system information is changed in the next change period.

 The notification as to whether the relay system information is changed is included at least once in one change period.

Data for transmission error checking of the relay common backhaul downlink physical control channel may be masked using a relay common identifier applicable to all relays interlocked with the base station.

The BS may transmit at least one of information indicating whether each BS access downlink includes a backhaul downlink signal and allocation information of a backhaul uplink subframe to a relay.

Information indicating whether each of the BS access downlinks includes a backhaul downlink signal and allocation information of a backhaul uplink subframe may be set differently for each relay or relay group interworking with the BS, The same applies to all relays that are connected.

The base station transmits resource allocation information for the backhaul downlink physical data channel and the backhaul uplink physical data channel transmitted by the relay to the base station to the relay and transmits the backhaul downlink physical data channel and relay to the base station The resource allocation information for the backhaul uplink physical data channel may include information on the range of the backhaul uplink physical data channel to which the resource allocation information is applied.

A backhaul downlink transmission method according to another aspect of the present invention relates to a transmission method of a mobile communication system in which a relay is communicated with a base station through a backhaul link and the base station or the relay transmits at least one Comprising the steps of: receiving data including a codeword; constructing response information using a bundling mode that forms one acknowledge information for all the received at least one codeword; and transmitting the configured response information to the counterpart .

The entirety of the at least one codeword may be contained in one subframe, and each of the codewords may be contained in another subframe.

When the bundling station releases the bundling mode, notifies the relay of the release of the bundling mode.

The present invention can effectively transmit and receive data between a relay and a base station in a wireless communication system in which a relay exists.

FIG. 1A is a diagram illustrating a relay usage model in which a coverage extension can be obtained using a relay. FIG.
1B shows a relay usage model for improving cell throughput using a relay.
2 is a diagram illustrating six signal transmission / reception links existing in a wireless communication system according to the present invention.
3 is a diagram showing a transmission / reception relationship of a base station access downlink signal of a base station and a relay.
4 is a diagram illustrating a transmission / reception relationship of a backhaul downlink signal between a base station and a relay according to an embodiment of the downlink transmission method of the present invention.
5 is a diagram illustrating a transmission / reception relationship of a backhaul downlink signal between a base station and a relay according to another embodiment of the downlink transmission method of the present invention.
6 is a diagram illustrating a transmission / reception relationship of a backhaul downlink signal between a base station and a relay according to another embodiment of the downlink transmission method of the present invention.
7 is a diagram illustrating a transmission / reception relationship of a backhaul downlink signal between a base station and a relay according to another embodiment of the downlink transmission method of the present invention.
8 is a diagram showing a transmission / reception relationship of a base station access uplink signal of a base station and a relay.
9 is a diagram illustrating a transmission / reception relationship of a backhaul uplink signal of a base station and a relay according to an embodiment of the backhaul uplink transmission method according to the present invention.
10 is a diagram illustrating a transmission / reception relationship of a backhaul uplink signal of a base station and a relay according to another embodiment of the backhaul uplink transmission method according to the present invention.
11 is a diagram illustrating a transmission / reception relationship of a backhaul uplink signal of a base station and a relay according to another embodiment of the backhaul uplink transmission method according to the present invention.
12 is a diagram illustrating a transmission / reception relationship of a backhaul uplink signal of a base station and a relay according to another embodiment of the backhaul downlink transmission method according to the present invention.
FIG. 13 is a diagram illustrating a frame structure of a relay and a base station when two different uplink timing configurations are simultaneously used according to a preferred embodiment of the uplink configuration method of the present invention. FIG.
Figure 14 illustrates various forms of backhaul uplink subframes according to preferred embodiments of the present invention.
FIG. 15 is a view showing a form of continuous backhaul uplink subframe when the independent backhaul uplink subframe is of type A of FIG. 14; FIG.
FIG. 16 is a diagram showing a form of a continuous backhaul uplink subframe when the independent backhaul uplink subframe is of type B of FIG. 14; FIG.
FIG. 17 is a diagram illustrating the shape of a continuous backhaul uplink subframe when the independent backhaul uplink subframe is of type C of FIG. 14; FIG.
FIG. 18 is a diagram showing a form of continuous backhaul uplink subframes when the independent backhaul uplink subframe is of the type D of FIG. 14; FIG.
19 illustrates preferred embodiments of a frame structure in the case where there are two backhaul uplink demodulation reference signals in a backhaul uplink subframe including fourteen symbols in FIG.
20 illustrates preferred embodiments of a frame structure in the case where there are two backhaul uplink demodulation reference signals in a backhaul uplink subframe including twelve symbols.
Figure 21 illustrates preferred embodiments of a frame structure in which one backhaul uplink demodulation reference signal is placed in a backhaul uplink subframe with 14 symbols.
22 illustrates preferred embodiments of a frame structure in the case where one backhaul uplink demodulation reference signal is placed in a backhaul uplink subframe having 12 symbols.
23 is a diagram illustrating a transmission period of relay system information according to an embodiment of the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be interpreted in an ideal or overly formal sense unless explicitly defined in the present application Do not.

The term "User Equipment (UE)" as used in this application includes a mobile station, a user terminal (UT), a wireless terminal, an access terminal (AT), a terminal, a subscriber unit, A subscriber station (SS), a wireless device, a wireless communication device, a wireless transmit / receive unit (WTRU), a mobile node, a mobile, or other terminology. Various embodiments of the user terminal may be used in a cellular telephone, a smart phone with wireless communication capability, a personal digital assistant (PDA) with wireless communication capability, a wireless modem, a portable computer with wireless communication capability, A gaming device having a wireless communication function, a music storage and playback appliance having wireless communication capability, an Internet home appliance capable of wireless Internet access and browsing, as well as a portable unit or terminals incorporating combinations of such functions But is not limited thereto.

The term 'base station' used in the present application is used to mean 'a control device for controlling one cell'. A 'physical base station' in an actual communication system can control a plurality of cells. In this case, a 'physical base station' can be considered to include a plurality of 'base stations' in the present invention. The 'relay' in the present invention is used to mean 'a control device for controlling one cell'. A 'physical relay' in an actual communication system can control a plurality of cells. In this case, 'physical relay' can be considered to include a plurality of 'relays' in the present invention. That is, a parameter differently allocated to each cell may be considered to assign different values to each 'base station' or 'relay'.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In order to facilitate the understanding of the present invention, the same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted.

2 shows six signal transmission / reception links existing in a wireless communication system according to the present invention.

2, the wireless communication system according to the present invention includes a base station 110, a relay 210, a base station terminal 310, and a relay terminal 320. The base station terminal 310 transmits and receives signals to and from a base station belonging to the base station cell. A link in which the base station 310 transmits a signal to the base station terminal 310 is referred to as a base station access downlink and a link in which the base station terminal 310 transmits a signal to the base station 110 is referred to as a base station access uplink access uplink.

The relay 210 operates as a base station terminal at the initial stage when the relay is installed. That is, the base station 110 regards the relay 210 as one base station terminal 310 and transmits / receives signals to / from the relay 210 through the base station access uplink / downlink. Let the relay operating mode when the relay operates in this manner be the terminal mode of the relay. In the terminal mode of the relay, the relay 210 exchanges information necessary for constructing the relay cell with the base station 110.

Then, the relay 210 configures its own cell as a base station and can transmit / receive signals to / from the terminal. In this case, let's say that the mode in which the relay operates is the base station mode of the relay. Let the terminal belonging to the relay cell be the relay terminal when the relay is in base station mode. It is also assumed that the relay 210 transmits a signal to the relay terminal 320 as a relay access downlink and the relay terminal 320 transmits a signal to the base station as a relay access uplink. A link in which the BS 110 transmits a signal to the relay 210 when the relay is in the BS mode is referred to as a backhaul downlink and a link in which the relay 210 transmits a signal to the BS 110 is referred to as a backhaul uplink Let's say a link (backhaul uplink).

The relay 210 may also transition to the terminal mode when it operates in the base station mode and timing synchronization of the uplink with the base station 110 is not suitable. The relay operating in the terminal mode performs random access and aligns the uplink timing synchronization with the base station. The relay then transitions to the base station mode and can transmit and receive signals to and from the relay terminal 320 again.

Hereinafter, the base station access downlink subframe and the relay access downlink subframe will be described in more detail.

The base station access downlink frame is composed of a plurality of base station access downlink subframes. The base station may transmit only the base station access downlink signal or only the backhaul downlink signal according to the base station access downlink sub-frame. The base station may also transmit the base station access downlink signal and the backhaul downlink signal together. At this time, the base station access downlink signal and the backhaul downlink signal can be transmitted in different areas. Here, the region means a combination of a time domain, a frequency domain, a spatial domain, a code domain, and the like. The base station access downlink signal may include a base station access downlink physical data channel, a base station access downlink physical control channel, a base station access downlink reference signal, a base station access synchronization signal, and the like, But may also include other channels or signals. The backhaul downlink signal may include a backhaul downlink physical data channel, a backhaul downlink physical control channel, a backhaul downlink reference signal, and may further include other channels or signals other than the explicitly mentioned channel or signal. have.

Meanwhile, the relay access downlink frame is composed of a plurality of relay access downlink subframes. The relay may transmit only the relay access downlink signal according to the relay access downlink subframe, or may receive only the backhaul downlink signal. The relay may also transmit the relay access downlink signal and receive the backhaul downlink signal. More specifically, the relay may transmit the relay access downlink signal over the relay access downlink subframe. Further, the relay may not transmit the relay access downlink signal over a part or the whole of the relay access downlink subframe to receive the backhaul downlink signal. Here, the region means a combination of a time domain, a frequency domain, a spatial domain, a code domain, and the like. According to one embodiment of the present invention, when a backhaul downlink signal is received in a relay access downlink subframe, the relay configures the relay access downlink subframe as an MBSFN subframe, and a relay access downlink signal is transmitted to the relay terminal You can also tell the area.

In the base station mode of the relay, the relay transmits a guard period before, after, or after receiving the backhaul downlink signal for switching between downlink transmission and downlink reception occurring at a radio frequency (RF) You can. During this guard interval, the relay does not receive the backhaul downlink signal and does not transmit the relay access downlink signal. Let the guard interval between the relay after transmitting the relay access downlink signal and before receiving the backhaul downlink signal be the downlink leading guard interval, GP1_DL, and let the length of GP1_DL be Tgp1_DL. Tgp1_DL is equal to or greater than the switching time from the downlink transmission to the downlink reception at the RF end of the relay. Let the guard interval between the relay after receiving the backhaul downlink signal and before transmitting the relay access downlink signal be the downlink posterior guard interval, GP2_DL, and the length of GP2_DL be Tgp2_DL. Tgp2_DL is equal to or greater than the switching time from the downlink reception to the downlink transmission occurring at the RF end of the relay.

Next, consider the timing alignment, i.e., the timing between the downlink transmission of the base station and the downlink transmission / reception of the relay.

In the terminal mode of the relay, the relay receives the base station access downlink signal transmitted from the base station. The base station access downlink signal arrives at the relay after a period of time equal to the propagation delay between the base station and the relay, which can be seen in FIG.

3 shows a transmission / reception relationship between a base station and a relay base station access downlink signal. Here, Tp denotes a signal transmission time between the base station and the relay.

In the relay base station mode, the interval of the backhaul downlink signal that can be transmitted and received between the base station and the relay is determined by the length of the guard interval, that is, the length Tgp1_DL of the downlink guard interval, the length Tgp2_DL of the downlink guard interval, And the time required for switching between the downlink transmission and the downlink reception in the RF stage of the relay, and the start time of the relay access downlink subframe.

The present invention proposes preferred embodiments of the timing relationship in the interval of the backhaul downlink signal that the base station and the relay can transmit and receive.

Before the concrete configuration, the following matters are assumed. The base station access downlink subframe is made up of L symbols, and the serial numbers of the symbols start from zero. Therefore, the symbol m means the (m + 1) th symbol of the base station access downlink subframe. Further, it is assumed that the relay access downlink subframe is composed of a plurality of symbols, and the serial numbers of the symbols start from zero. Let k be the number of symbols to which the relay access downlink physical control channel of the relay access downlink signal in the relay access downlink subframe is transmitted. k is 0 or a positive integer. The base station access downlink signal transmitted by the base station is received by the relay after Tp. It is also assumed that the length of the base station access downlink subframe and the length of the relay access downlink subframe are equal to each other.

4 to 7, a description will be made of preferred embodiments according to the backhaul downlink transmission method of the present invention.

4 is a diagram illustrating a transmission / reception relationship of a backhaul downlink signal between a base station and a relay according to an embodiment of the downlink transmission method of the present invention.

FIG. 4 shows the frame structure of the base station and the relay when k = 1 and L = 14 are assumed. Further, it is assumed that the switching time from the downlink transmission to the downlink reception in the RF stage of the relay and the switching time from the downlink reception to the downlink transmission in the relay RF are larger than the cyclic prefix of the symbol, respectively do.

In the embodiment shown in FIG. 4, the relay sets the start time of the relay access downlink subframe backward by Tgp2_DL at the time when the first symbol of the base station access downlink subframe starts to be received by the relay. In this case, the base station can transmit the backhaul downlink signal from the symbol k + 1 to the last symbol of the base station access downlink subframe. k has already been described above that the relay access downlink physical control channel 410 is the number of symbols to be transmitted. The relay may receive the backhaul downlink signal from symbol k + 1 to the last symbol of the base station access downlink subframe. For example, the frame configuration and the timing relationship of the base station and the relay shown in FIG. 4 will be described. The base station transmits the backhaul downlink signals of the symbols 2 to 13 and the relay receives the backhaul downlink signals of the symbols 2 to 13 .

The first symbol of the backhaul downlink signal that can be transmitted and received by the base station and the relay varies depending on the time interval of the relay access downlink physical control channel 410 in the relay access downlink signal, that is, the number k of symbols There is a bar. In addition, the first symbol of the backhaul downlink signal that can be transmitted and received between the base station and the relay may also vary according to the number of symbols to which the base station access downlink physical control channel of the base station access downlink signal is transmitted. In this case, the base station can inform the relay of the position information of the first symbol of the backhaul downlink signal. The position information of the first symbol of the backhaul downlink signal may be transmitted through upper layer signaling (RRC signaling in case of 3GPP) or backhaul downlink physical control channel.

5 illustrates a transmission / reception relationship of a backhaul downlink signal between a base station and a relay according to another embodiment of the downlink transmission method of the present invention.

Fig. 5 also shows the frame structure of the base station and the relay in the case of k = 1 and L = 14, as in Fig. It is also assumed that the switching time from the downlink transmission to the downlink reception in the RF stage of the relay and the switching time from the downlink reception to the downlink transmission in the relay RF are greater than the cyclic prefix of the symbol, respectively.

In the embodiment of FIG. 5, the relay identifies the start time of the relay access downlink subframe by k symbols (e.g., in FIG. 5) at the time when the first symbol of the base station access downlink subframe begins to be received by the relay 1 symbol) and the length of Tgp1_DL. In this case, the base station may transmit the backhaul downlink signal from the first symbol to the symbol n of the base station access downlink subframe. Where n = Lk-2. The relay can receive the backhaul downlink signal from the first symbol to symbol n of the base station access downlink subframe. In the embodiment of FIG. 5, the base station transmits the backhaul downlink subframes from 0 to 11, and the relay receives the backhaul downlink subframes from 0 to 11. FIG.

6 illustrates a transmission / reception relationship of a backhaul downlink signal of a base station and a relay according to another embodiment of the downlink transmission method of the present invention.

FIG. 6 also shows the frame structure of the base station and the relay in the case of k = 1 and L = 14, as in FIGS. 4 and 5. FIG. It is also assumed that the switching time from the downlink transmission to the downlink reception at the RF end of the relay and the switching time from the downlink reception to the downlink transmission at the relay RF are greater than the cyclic prefix of the symbol, respectively.

6 illustrates a structure of the backhaul downlink subframe transmitted by the base station and the structure of the backhaul downlink subframe received by the relay according to the length of the signal transmission time Tp, as shown in FIGS. 6 (a) through 6 (c) Respectively. 6 (a) shows a case where Tp is 0, FIG. 6 (b) shows a case where Tp has a positive real value larger than 0, and FIG. 6 (c) And has a positive real value. That is, FIG. 6 (a) to FIG. 6 (c) shows a case in which the Tp value gradually increases.

In the embodiment of FIG. 6, the relay sets the start time of the relay access downlink subframe to be similar to the start time of the base station access downlink subframe. As a method for this, the relay indicates the transmission advance time of the relay access downlink subframe by the timing advance information that the base station transmits to the relay at the time when the first symbol of the base station access downlink subframe starts to be received by the relay You can use the forward setting method for half the time. With this method, the start time of the relay access downlink subframe may be substantially the same as the start time of the base station access downlink subframe. In this case, the base station can transmit the backhaul downlink signal from symbol m to symbol n of the base station access downlink subframe. The relay may receive the backhaul downlink signal from symbol m to symbol n of the base station access downlink subframe. Where m? K and n? L-2.

On the other hand, the lengths Tgp1_DL and Tgp2_DL of the guard interval can be changed according to the length of the signal transmission time Tp, and the interval of the backhaul downlink signal that can be transmitted and received between the relay and the base station can be changed. The signal transmission time Tp may vary depending on the position where the relay is installed. The base station can transmit information on the interval of the backhaul downlink signal to be relayed by the relay to the relay through higher layer signaling (RRC signaling in case of 3GPP). The index of the first symbol and the index of the last symbol of the backhaul downlink signal can be informed by the embodiment of the information on the interval of the backhaul downlink signal, respectively. In another embodiment of the interval information of the backhaul downlink signal, the interval of the plurality of backhaul downlink signals may be predetermined and one of them may be informed. The relay receives the backhaul uplink signal based on the backhaul downlink signal interval information received from the base station.

6, the BS excludes symbols corresponding to the number of symbols to which the relay access downlink control channel is transmitted from the first symbol of the BS access downlink sub-frame, The backhaul downlink signal can be transmitted using the symbols for transmitting the backhaul downlink signal having the maximum value up to the previous symbol except for the last symbol. Here, the start symbol and the end symbol of the symbols for transmitting the backhaul downlink signal may vary according to the length of the signal transmission time of the backhaul downlink.

The first symbol of the backhaul downlink signal that can be transmitted and received by the base station and the relay varies depending on the number k of symbols to which the relay access downlink physical control channel of the relay access downlink signal is transmitted. In addition, the first symbol of the backhaul downlink signal that can be transmitted and received between the base station and the relay may also vary according to the number of symbols to which the base station access downlink physical control channel of the base station access downlink signal is transmitted. In this case, the base station can inform the relay of the position information of the first symbol of the backhaul downlink signal. The position information of the first symbol of the backhaul downlink signal may be transmitted through higher layer signaling (RRC signaling in case of 3GPP) or backhaul downlink physical control channel.

6 (a) to 6 (c), it can be seen that the intervals of the backhaul downlink signals transmitted and received by the base station and the relay are different according to Tp. That is, in the case of 6 (a) where Tp is 0, the backhaul downlink signal interval is a backhaul downlink signal interval from symbol 2 to symbol 12, and in the case of FIG. 6 (b) where Tp is a positive real number, To 12 is the backhaul downlink signal interval. 6 (c) in which the signal transmission time Tp is larger than Tp in FIG. 6 (b), the backhaul downlink signal interval from the symbol 1 to the symbol 11 can be obtained. In addition, the backhaul downlink signal interval may be symbol 10 in symbol 1, symbol 9 in symbol 1, etc. according to signal transmission time Tp. The backhaul downlink signal interval information may be one of the above-mentioned intervals.

7 is a diagram illustrating a transmission / reception relationship between a base station and a relay of a backhaul downlink signal according to another embodiment of the downlink transmission method of the present invention.

FIG. 7 also shows the frame structure of the base station and the relay in the case of k = 1 and L = 14, as in FIGS. 4 to 6. FIG.

7, the switching time from the downlink transmission to the downlink reception in the RF stage of the relay and the switching time from the downlink reception to the downlink reception in the RF of the relay are different from those of the previous embodiments. And that the switching time to the link transmission is much smaller than the cyclic prefix of the symbol, respectively. In this case, the guard intervals GP1_DL and GP2_DL are not explicitly shown in FIG. 7 because they are included in the cyclic prefix interval of the symbol.

In the embodiment of FIG. 7, the relay sets the start time of the relay access downlink subframe to the time when the first symbol of the base station access downlink subframe starts to be received by the relay. In this case, the base station may transmit the backhaul downlink signal from the symbol k to the last symbol of the base station access downlink subframe. The relay can receive the backhaul downlink signal from symbol k to the last symbol of the base station access downlink subframe.

The first symbol of the backhaul downlink signal that can be transmitted and received by the base station and the relay has been already determined according to the number k of symbols to which the relay access downlink physical control channel of the relay access downlink signal is transmitted. In addition, the first symbol of the backhaul downlink signal that can be transmitted and received between the base station and the relay may also vary according to the number of symbols to which the base station access downlink physical control channel of the base station access downlink signal is transmitted. In this case, the base station can inform the relay of the position information of the first symbol of the backhaul downlink signal. The position information of the first symbol of the backhaul downlink signal may be transmitted through higher layer signaling (RRC signaling in case of 3GPP) or backhaul downlink physical control channel.

Up to now, preferred embodiments of the backhaul downlink transmission method according to the present invention have been described.

Hereinafter, preferred embodiments of the uplink transmission method according to the present invention will be described. First, a backhaul / base station access / relay access uplink subframe to which the present invention is applied will be described.

The base station access uplink frame is composed of a plurality of base station access uplink subframes. The base station may receive only the base station access uplink signal or only the backhaul uplink signal according to the base station access uplink sub-frame. The base station may also receive the base station access uplink signal and the backhaul uplink signal together. At this time, the base station access downlink signal and the backhaul downlink signal can be received in different areas. Here, the region means a combination of a time domain, a frequency domain, a spatial domain, a code domain, and the like. The base station access uplink signal includes a base station access uplink physical data channel, a base station access uplink physical control channel, a base station access uplink demodulation reference signal, and a base station access uplink channel measurement reference signal. The base station access uplink signal may also include signals other than the signals explicitly mentioned above.

Meanwhile, the relay uplink frame is composed of a plurality of relay uplink subframes. The relay uplink subframe may be a relay access uplink subframe or the backhaul uplink subframe. The relay can receive the relay access uplink signal through the relay access uplink subframe in the base station mode of the relay. The relay access uplink signal includes a relay access uplink physical data channel, a relay access uplink physical control channel, a relay access uplink demodulation reference signal, and a relay access uplink channel measurement reference signal. The relay access uplink signal may also include other signals than the signal or channel mentioned.

The relay may also transmit the backhaul uplink signal to the backhaul uplink subframe. The backhaul uplink signal includes a backhaul uplink physical data channel, a backhaul uplink physical control channel, a backhaul uplink demodulation reference signal, and a backhaul uplink channel measurement reference signal. The backhaul uplink signal may also include other signals than the above-mentioned signals or channels.

The relay may have a guard period before and after transmitting the backhaul uplink signal for switching between the uplink transmission and the uplink reception at the RF end of the relay. During this guard interval, the relay neither transmits the backhaul uplink signal nor receives the relay access uplink signal. Let the guard interval between the relay after receiving the relay access uplink signal and before transmitting the backhaul uplink signal be the preceding guard interval, GP1_UL, and let the length of GP1_UL be Tgp1_UL. Tgp1_UL must be greater than or equal to the transition time from the uplink reception at the RF end of the relay to the uplink transmission. Let the guard interval between the relay after transmitting the backhaul uplink signal and before receiving the relay access uplink signal be the following guard interval, GP2_UL, and let the length of GP2_UL be Tgp2_UL. Tgp2_UL must be greater than or equal to the transition time from the uplink transmission to the uplink reception in the relay's RF. The guard intervals GP1_UL and GP2_UL may be located in the backhaul uplink subframe.

Next, a discussion will be made with respect to timing between backhaul timing alignment, i.e., relay uplink transmission and base station uplink reception.

8 shows a transmission / reception relationship of a base station access uplink signal of a base station and a relay.

8, the upper two subframe structures represent two downlink subframe structures related to the transmission of the base station and the subsequent reception of the relay, and the two lower subframe structures are associated with the transmission of the relay and hence the reception of the base station And shows two uplink subframe structures.

In Fig. 8, TA indicates the time indicated by the timing advance information. Here, it is assumed that the time indicated by the timing advance information, that is, TA is 2 x Tp. It is also assumed that the base station starts to transmit the base station access downlink subframe and the base station starts to receive the base station access uplink subframe.

The relay transmits the base station access uplink signal to the base station in the terminal mode of the relay. The relay starts to transmit the base station access uplink signal before the time indicated by the timing advance information that the base station transmits to the relay from the time when the relay starts receiving the base station access downlink signal. The base station access uplink signal arrives at the base station after Tp. This timing relationship can be confirmed through Fig.

 In the relay base station mode, the interval of the backhaul uplink signal that can be transmitted and received between the base station and the relay is determined by the lengths Tgp1_UL and Tgp2_UL of the guard interval and the time required for switching between the uplink transmission and the uplink reception in the relay RF, Or the start time of the relay access uplink subframe.

The present invention proposes several methods related to the configuration of a backhaul uplink signal that can be transmitted and received between a base station and a relay, and these methods will be described in detail through the following embodiments.

Before the concrete configuration, the following matters are assumed. The base station access uplink subframe is composed of R symbols, and the serial numbers of the symbols start from zero. Therefore, the symbol p indicates the (p + 1) th symbol of the base station access uplink subframe. It is assumed that the backhaul uplink subframe is composed of a plurality of symbols. The serial number of the backhaul uplink signal symbol in the backhaul uplink subframe is given in view of the backhaul uplink signal reaching the base station access uplink subframe. For example, the backhaul uplink signal symbol p transmitted by the relay is received by the base station on the symbol p of the base station access uplink subframe. Let the backhaul uplink signal transmitted by the relay be received by the base station after Tp. The length of the base station access uplink sub-frame and the length of the backhaul uplink sub-frame are equal to each other.

9 to 12, preferred embodiments of the backhaul uplink transmission method of the present invention will be described.

9 is a diagram illustrating a transmission / reception relationship between a base station and a relay of a backhaul uplink signal according to an exemplary embodiment of the present invention.

In the embodiment of FIG. 9, it is assumed that R = 14. Further, it is assumed that the switching time from the uplink transmission to the uplink reception and the switching time from the uplink reception to the uplink transmission at the RF stage of the relay are larger than the cyclic prefix of the symbol, respectively.

In the embodiment of FIG. 9, the relay sets the start time of the backhaul uplink subframe by Tgp2_UL at the time when the relay transmits the base station access uplink signal in the terminal mode of the relay. In this case, the base station can receive the backhaul uplink signal from the second symbol to the last symbol of the base station access uplink sub-frame. The relay may transmit the backhaul uplink signal from the second symbol to the last symbol of the backhaul uplink subframe. The transmission of the backhaul uplink signal of the relay can start from behind by one symbol length when the relay transmits the base station access uplink signal in the terminal mode of the relay. The transmission of the backhaul uplink signal of the relay may also start from Tgp1_UL at the beginning of the backhaul uplink subframe as shown in FIG. Here, it is assumed that the sum of Tgp1_UL and Tgp2_UL is equal to the length of one symbol.

The starting point of the backhaul uplink subframe and the transmission start point of the backhaul uplink signal mentioned above can be applied at least when the relay switches from the terminal mode of the relay to the base station mode of the relay. After the relay switches to the base station mode of the relay, the start time of the backhaul uplink subframe and the transmission start time of the backhaul uplink signal can be changed according to the timing advance information transmitted to the relay by the base station, respectively.

10 illustrates a transmission / reception relationship of a backhaul uplink signal of a base station and a relay according to another embodiment of the backhaul uplink transmission method according to the present invention.

In the embodiment of FIG. 10, it is assumed that R = 14 as in FIG. Further, it is assumed that the switching time from the uplink transmission to the uplink reception and the switching time from the uplink reception to the uplink transmission at the RF stage of the relay are larger than the cyclic prefix of the symbol, respectively.

In the embodiment of FIG. 10, the relay sets the start time of the backhaul uplink subframe by Tgp1_UL at the time when the relay transmits the base station access uplink signal in the terminal mode of the relay. In this case, the base station can receive the backhaul uplink signal from the first symbol to the last symbol from the first symbol of the base station access uplink sub-frame. The relay can transmit the backhaul uplink signal from the first symbol to the last symbol from the backhaul uplink subframe.

The transmission of the backhaul uplink signal of the relay may start at the time when the relay transmits the base station access uplink signal in the terminal mode of the relay. Also, transmission of the relay backhaul uplink signal may start from Tgp1_UL at the start of the backhaul uplink subframe, as shown in FIG.

The starting point of the backhaul uplink subframe and the transmission start point of the backhaul uplink signal mentioned above can be applied at least when the relay switches from the terminal mode of the relay to the base station mode of the relay. After the relay switches to the base station mode of the relay, the start time of the backhaul uplink subframe and the transmission start time of the backhaul uplink signal can be changed according to the timing advance information transmitted to the relay by the base station, respectively.

11 illustrates a transmission / reception relationship of a backhaul uplink signal of a base station and a relay according to another embodiment of the backhaul uplink transmission method according to the present invention.

In the embodiment of FIG. 11, it is assumed that R = 14 as in FIGS. 9 and 10. It is also assumed that the switching time from the uplink transmission to the uplink reception and the switching time from the uplink reception to the uplink transmission at the RF stage of the relay are respectively greater than the cyclic prefix of the symbols.

In the embodiment of FIG. 11, the start time of the backhaul uplink subframe is set equal to the start time of the base station access uplink subframe. 11 (a) to 11 (c) show the change of the interval of the backhaul uplink signal transmitted and received by the relay and the base station according to the change of the Tp length in this case. FIG. 11A shows a case where Tp is 0, FIG. 11B shows a case where Tp is a positive real number, FIG. 11C shows a case where Tp is a real number larger than a case of 11 (b) Respectively. 11 (a) to 11 (c), the section of the backhaul uplink signal is from symbol 1 to symbol 12 in FIG. 11 (a) where Tp is zero. In Fig. 11 (b) having a positive real number Tp, the interval of the backhaul uplink signal is from symbol 1 to symbol 13, and in Fig. 11 (c) with Tp larger than 11 (b) 13 backhaul uplink signal interval. It should be understood that the backhaul uplink signal interval may be symbol 13 in symbol 3 and symbol 13 in symbol 4 depending on the length of Tp. The backhaul uplink signal interval information may be one of the above mentioned intervals.

In the embodiment according to FIG. 11, the base station can receive the backhaul uplink signal from symbol p to symbol q in the base station access uplink subframe. The relay can transmit the backhaul uplink signal from symbol p to symbol q of the backhaul uplink subframe. Where p? 1 and q? R-1. That is, the relay transmits the backhaul uplink signal using the symbols transmitted from the second symbol of the backhaul uplink subframe to the last symbol, and transmits the backhaul uplink signal using the balls transmitted through the backhaul uplink signal. Here, it can be seen from FIG. 11 that the start symbol and the end symbol of the symbols for transmitting the backhaul uplink signal can be changed according to at least one of the length of the signal transmission time of the backhaul uplink and the transmission / reception switching time of the relay.

In the embodiment of FIG. 11, the relay sets the start time of the backhaul uplink subframe to be similar to the start time of the base station access uplink subframe. As a method of realizing this, a relay is a method for relaying the start time of the backhaul uplink subframe at a time point when the relay transmits the base station access uplink signal in the terminal mode of the relay, the time indicated by the timing advance information transmitted from the base station to the relay By setting it backward by a half, the start time of the backhaul uplink subframe may be substantially the same as the start time of the base station access uplink subframe. The transmission of the backhaul uplink signal of the relay may start from Tgp1_UL backward at the beginning of the backhaul uplink subframe. The lengths Tgp1_UL and Tgp2_UL of the guard interval can be changed according to the length of the Tp and the interval of the backhaul uplink signal that can be transmitted and received between the relay and the base station can be changed. Depending on where the relay is installed, the Tp may vary.

Here, the base station can transmit information on the interval of the backhaul uplink signal to be relayed by the relay to the relay through higher layer signaling (RRC signaling in case of 3GPP). The index of the first symbol and the last symbol of the backhaul uplink signal can be informed by the embodiment of the information on the interval of the backhaul uplink signal, respectively.

In another embodiment of the interval information of the backhaul uplink signal, the interval of the plurality of backhaul uplink signals may be predetermined and one of them may be informed. The relay transmits the backhaul uplink signal based on the backhaul uplink signal interval information received from the base station.

The starting point of the backhaul uplink subframe and the transmission start point of the backhaul uplink signal mentioned above can be applied at least when the relay switches from the terminal mode of the relay to the base station mode of the relay. After the relay switches to the base station mode of the relay, the start time of the backhaul uplink subframe and the transmission start time of the backhaul uplink signal can be changed according to the timing advance information transmitted to the relay by the base station, respectively.

FIG. 12 illustrates a transmission / reception relationship of a backhaul uplink signal of a base station and a relay according to another embodiment of a backhaul downlink transmission method according to the present invention.

It is assumed that R = 14 in the embodiment of FIG. 12, the switching time from the uplink transmission to the uplink reception in the RF of the relay and the switching time from the uplink reception to the uplink transmission in the RF of the relay are each a cycle of symbols It is assumed that it is much smaller than the transposition. In this case, since the guard intervals GP1_UL and GP2_UL are included in the cyclic prefix periods of the symbols, they are not explicitly shown in FIG.

In the embodiment of FIG. 12, the relay sets the start time of the backhaul uplink subframe to the time when the relay transmits the base station access uplink signal in the terminal mode of the relay. In this case, the base station can receive the backhaul uplink signal from the first symbol to the last symbol of the base station access uplink sub-frame. The relay can transmit the backhaul uplink signal from the first symbol to the last symbol of the backhaul uplink subframe. The transmission of the relay backhaul uplink signal may start at the beginning of the backhaul uplink subframe.

The starting point of the backhaul uplink subframe and the transmission start point of the backhaul uplink signal mentioned above can be applied at least when the relay switches from the terminal mode of the relay to the base station mode of the relay. After the relay switches to the base station mode of the relay, the start time of the backhaul uplink subframe and the transmission start time of the backhaul uplink signal can be changed according to the timing advance information transmitted to the relay by the base station, respectively.

The preferred embodiments of the backhaul uplink transmission method according to the present invention have been described above.

Next, a description will be given with respect to the downlink and uplink timing configurations.

With respect to the downlink and uplink transmission timings as described above, the relay can transmit the switching time information between the transmission and reception at the RF end of the relay to the base station through the upper layer signaling (RRC signaling in 3GPP). The switching time between transmission and reception at the RF end of the relay is determined, for example, at the RF end of the relay, the switching time from the downlink transmission to the downlink reception, the switching time from the downlink reception to the downlink transmission, To the uplink reception, the switching time from the uplink reception to the uplink transmission, and the like. Using this information, the base station can determine the interval configuration information of the backhaul downlink signal that can be transmitted and received with the relay, the interval configuration information of the backhaul uplink signal, and the like.

In connection with the backhaul downlink, the base station informs the relay of the interval configuration information of the backhaul downlink signal through higher layer signaling (in the case of 3GPP, it can be RRC signaling), and one or a plurality of backhaul downlink By selecting the interval configuration of the link signal, the base station and the relay can transmit and receive backhaul downlink signals. Here, the selection of the interval configuration of the backhaul downlink signal may vary depending on the deployment method of the relay or the time. At this time, the base station transmits the interval configuration information of the backhaul downlink signal to the relay. Here, the interval configuration information of the backhaul downlink signal includes the configuration shown in the embodiments of FIGS. 3 to 7, that is, the information about the symbols through which the signals are actually transmitted among all the base station access downlink subframes, And information on the downlink transmission timing.

Also, the base station can transmit and receive the backhaul downlink signal between the base station and the relay using one or a plurality of predefined backhaul downlink signal constellations, without informing the relay of the interval configuration information of the backhaul downlink signals. have.

In connection with the backhaul uplink, the base station informs the relay of the interval configuration information of the backhaul uplink signal through higher layer signaling (in the case of 3GPP, it may be RRC signaling), and transmits one or more backhaul uplink By using the interval configuration of the signal, the base station and the relay may transmit and receive backhaul uplink signals. Here, the selection of the interval configuration of the backhaul uplink signal may vary depending on the deployment method of the relay or the time, and the base station transmits the interval configuration information of the backhaul uplink signal to the relay. Here, the interval configuration information of the backhaul uplink signal includes information on the configurations shown in the embodiments of FIGS. 9 to 12, that is, information about the symbols to which signals are actually transmitted among the entire backhaul uplink subframes, Link transmission and the backhaul uplink reception timing of the base station.

Also, the base station does not inform the relay of the interval configuration information of the backhaul uplink signal, but uses the interval configuration of one or more predefined backhaul uplink signals so that the base station and the relay can transmit and receive the backhaul uplink signals have.

Meanwhile, the relay may configure the relay access uplink subframe as the relay access uplink channel measurement subframe to receive the relay access uplink channel measurement reference signal from the relay terminal. The relay at a specific symbol of the relay access uplink channel measurement sub-frame may receive the relay access uplink channel measurement reference signal transmitted by the relay terminal. All the relay access uplink subframes may be configured as relay access uplink channel measurement subframes, and some relay access uplink subframes may be configured as relay access uplink channel measurement subframes. The configuration information of the relay access uplink channel measurement subframe may be determined by the relay and transmitted to the base station through higher layer signaling (in the case of 3GPP, RRC signaling), or may be determined by the base station, (In the case of 3GPP, it may be RRC signaling).

When the relay transmits the backhaul uplink subframe, the interval of the backhaul uplink signal transmitted by the relay is a relay access uplink subframe immediately before or after the backhaul uplink subframe is a relay access uplink channel measurement subframe And it is possible to confirm the related embodiment in FIG.

FIG. 13 shows a frame structure of a relay and a base station when two different uplink timing configurations are simultaneously used according to a preferred embodiment of the uplink configuration method of the present invention.

Here, GP1_UL and GP2_UL are uplink and posterior guard intervals, respectively, and lengths of guard intervals are Tgp1_UL and Tgp2_UL, respectively. Tp denotes a signal transmission time between the base station and the relay. It is assumed that the relay access uplink sub-frame 1310 and the backhaul uplink sub-frame 1320 are each composed of 14 symbols. It is also assumed that the switching time from the uplink transmission to the uplink reception and the switching time from the uplink reception to the uplink transmission in the RF of the relay are larger than the cyclic prefixes of the symbols in the RF stage of the relay.

13 (a) shows a case where the relay access uplink sub-frame 1310 is not a relay access uplink channel measurement sub-frame. In this case, the base station can receive the backhaul uplink signal from the second symbol to the last symbol of the base station access uplink subframe, as in a preferred embodiment of the uplink transmission method of the present invention described with reference to FIG. The relay may transmit the backhaul uplink signal from the second symbol to the last symbol of the backhaul uplink sub-frame 1320. [

13 (b) shows a case where the relay access uplink subframe is a relay access uplink channel measurement subframe. At this time, the relay may not receive the last symbol of the relay access uplink sub-frame. The backhaul uplink may receive the backhaul uplink signal from the first symbol to the last symbol of the base station access uplink subframe, as in a preferred embodiment of the uplink transmission method of the present invention described with reference to FIG. The relay can transmit the backhaul uplink signal from the first symbol to the last symbol of the backhaul uplink subframe.

13 (a) and 13 (b), it can be seen that the relay receives the relay access uplink subframe from the same point in time. 13A and 13B, although the periods assigned to the backhaul uplink signals are different from each other, it can be seen that the base station receives symbols 1 to 13 of the backhaul uplink signal at the same time. That is, although the number of backhaul uplink signal symbols transmitted by the relay may be 13 or 14, they are transmitted at the same time. Therefore, the base station does not need to transmit different timing advance information to the relay for each of the cases of Figs. 13 (a) and 13 (b). In the case of FIG. 13A, the relay transmits the backhaul uplink signal from one symbol after the reference point. In FIG. 13B, the relay transmits the backhaul uplink signal from the reference point. Here, the reference time point may be the starting point of the backhaul uplink subframe in FIG. 13 (b).

In summary, in a backhaul downlink between a base station and a relay according to an aspect of the present invention, a base station and a relay transmit / receive a backhaul downlink signal using information on a backhaul downlink signal interval configuration or a backhaul downlink signal interval, do. Also, in the backhaul uplink between the base station and the relay according to the present invention, the base station and the relay transmit / receive the backhaul uplink signal using the information of the interval configuration of the backhaul uplink signal or the interval of the backhaul uplink signal.

Hereinafter, backhaul uplink transmission according to another aspect of the present invention will be described.

The backhaul uplink subframe may comprise a backhaul uplink signal interval and a guard interval. The backhaul uplink signal includes a backhaul uplink physical data channel, a backhaul uplink physical control channel, a backhaul uplink demodulation reference signal, and a backhaul uplink channel measurement reference signal. The backhaul uplink signal may also include other signals other than those signals or channels explicitly mentioned.

A guard interval may be provided at the front or back of the backhaul uplink subframe or at the front and back of the backhaul uplink subframe due to the signal transmission time of the base station and the relay and the switching time between the backhaul uplink transmission and the relay access uplink reception at the RF end of the relay . The length of the guard interval may be freely configured, and the lengths of the guard intervals of the front portion and the rear portion may be equal to or different from each other.

The relay 210 performing the uplink transmission according to the present invention constructs an uplink frame in which a first backhaul uplink demodulation reference signal and a second backhaul uplink demodulation reference signal are arranged in one backhaul uplink subframe do. Also, the relay may form an uplink frame in which only one backhaul uplink demodulation reference signal is arranged in one backhaul uplink subframe. The relay 210 according to the present invention may also be configured such that when two or more backhaul uplink subframes to be transmitted to the base station are to be relayed, one of the backhaul uplink subframes contacts another backhaul uplink subframe The guard interval is replaced with a backhaul uplink signal interval to adaptively configure a backhaul uplink subframe.

The base station 110 according to the present invention can transmit information on the type of the independent backhaul uplink subframe to be used by the relay to the relay in advance, receive two or more consecutive backhaul uplink subframes from the relay, And derives the shape of the two or more consecutive backhaul uplink subframes from the set of independent backhaul uplink subframes.

Figure 14 illustrates various forms of backhaul uplink subframes according to preferred embodiments of the present invention.

Referring to the backhaul uplink subframe types shown in FIG. 14, according to the presence or absence of the guard interval and the guard interval, a type A in which a guard interval is arranged on both sides of the backhaul uplink signal interval, Type B in which a guard interval is arranged, type C in which a guard interval is arranged only after a backhaul uplink signal interval, and type D in which only a backhaul uplink signal interval and a guard interval are not allocated can be configured . Herein, the protection interval arranged in front of the signal interval is referred to as a preceding guard interval, and the guard interval arranged behind the signal interval will be referred to as a rearward guard interval.

The base station and the relay can perform backhaul uplink transmission / reception using a fixed or predefined backhaul uplink subframe. It is also possible to define a plurality of types of subframe configurations shown in FIG. 13 and use a method of selecting a specific type through signaling according to a situation. In this case, the base station can transmit the backhaul uplink subframe type information to be used by the relay when allocating one independent backhaul uplink subframe to the relay. Here, the type information of the independent backhaul uplink subframe includes, for example, information about a type A, a type B, a type C, and a type D, which are types of backhaul uplink subframes shown in FIG. 14 . That is, the BS selects one of at least one type of the backhaul UL subframe previously established between the BS and the relay, and transmits information on the selected subframe type to the upper layer signaling (which may be RRC signaling in case of 3GPP) To the relay.

On the other hand, it may happen that the base station allocates the backhaul uplink subframes temporally continuous to the relay. In this case, the relay transmits the continuous backhaul uplink subframe in time, wherein the back guard interval of the first backhaul uplink subframe and the first guard interval of the next backhaul uplink subframe may be unnecessary. Therefore, when the BS allocates the BS uplink subframe in time to the relay, the relay adaptively transmits the backhaul uplink subframe in different forms. In the present application, the 'adaptive backhaul uplink subframe type Quot;

15 to 18 illustrate a form of a backhaul uplink subframe according to a variation of the number of backhaul uplink subframes to be continuously transmitted according to preferred embodiments of the present invention.

When the relay transmits an independent backhaul uplink subframe, the form of the backhaul uplink subframe is one of Type A, Type B, Type C, and Type D shown in FIG. Here, "independent backhaul uplink subframe transmission" means a case in which a backhaul uplink subframe is not transmitted immediately after the transmission of one backhaul uplink subframe and immediately before transmission of the backhaul uplink subframe.

FIG. 15 shows a continuous backhaul uplink subframe in the case where the type of the independent backhaul uplink subframe is Type A of FIG.

FIG. 15 shows the shape of a backhaul uplink subframe according to the number of backhaul uplink subframes to be continuously transmitted when a subframe requires a guard interval in a front part and a back part as in the type A. That is, when two consecutive backhaul uplink subframes are transmitted, the backhaul uplink subframes are transmitted in the order of type B and type C, respectively. When N consecutive backhaul uplink subframes are transmitted, the first and second backhaul uplink subframes are transmitted in the form of type B and type C, respectively, and the N-2 backhaul uplink subframes therebetween are of type D format.

FIG. 16 shows a continuous backhaul uplink subframe in the case where the type of the independent backhaul uplink subframe is Type B in FIG.

Referring to FIG. 16, when one independent backhaul uplink subframe transmitted by the relay requires a guard interval in the former part as in the type B, the backhaul uplink according to the number of backhaul uplink subframes The form of the subframe can be confirmed. When transmitting N consecutive backhaul uplink subframes, the first backhaul uplink subframe is transmitted in type B format and the N-1 backhaul uplink subframes thereafter are transmitted in type D format.

FIG. 17 shows a form of continuous backhaul uplink subframe when the type of the independent backhaul uplink subframe is Type C of FIG.

That is, FIG. 17 illustrates a case where one independent backhaul uplink subframe transmitted by a relay requires a guard interval at the back of the backhaul as in Type C, and a backhaul uplink sub- Shows the type of frame. When transmitting N consecutive backhaul UL subframes, the last backhaul UL subframe is transmitted in the form of type C, and the N-1 backhaul UL subframes preceding it are transmitted in the form of type D .

FIG. 18 shows a continuous backhaul uplink subframe in the case where the type of the independent backhaul uplink subframe is Type D of FIG.

If one independent backhaul uplink subframe transmitted by the relay does not need a guard interval as in Type D, all backhaul uplink subframes, regardless of the number of backhaul uplink subframes continuously transmitted as shown in FIG. 18, It can be seen that it is transmitted in the form of type D.

15 through 18, when a relay has two or more backhaul uplink subframes to be transmitted to a base station, if the two or more backhaul uplink subframes are arranged consecutively, The guard interval located at a position in contact with the frame is replaced with a backhaul uplink signal interval to adaptively construct a backhaul uplink subframe.

Also, although the relay does not explicitly inform the base station of the type of the backhaul uplink subframe it transmits, if the base station allocates a temporally continuous backhaul uplink subframe to the relay, the base station implicitly allocates the backhaul uplink subframe, The uplink sub-frame type can be known. That is, when the base station receives two or more consecutive backhaul uplink subframes from the relay, the base station may infer the form of two or more consecutive backhaul uplink subframes from the form of a predetermined independent backhaul uplink subframe .

Hereinafter, the internal structure of the backhaul uplink subframe will be described.

The backhaul uplink subframe when the relay transmits the backhaul uplink physical data may be composed of a symbol through which the backhaul uplink physical data is transmitted and a symbol through which the backhaul uplink demodulation reference signal is transmitted and a guard interval. Here, the guard interval may be located at the front or rear portion of the backhaul uplink subframe, or at the front portion and the rear portion of the backhaul uplink subframe. The length of the front guard interval and the length of the rear guard interval may be the same or different from each other.

19-22 illustrate preferred embodiments of a backhaul uplink subframe structure according to the present invention.

Here, the number of symbols constituting the backhaul uplink subframe, the number of symbols to which the backhaul uplink physical data is transmitted, the number of symbols to which the backhaul uplink demodulation reference signal is transmitted, and the length of the guard interval, A change in the structure of the subframe can be confirmed.

FIGS. 19 and 20 illustrate the arrangement of the backhaul uplink demodulation reference signal in the backhaul uplink subframe when there are two backhaul uplink demodulation reference signals 810 and 820 in the backhaul uplink subframe. FIGS. 19 and 20 show when the length of the backhaul uplink subframe is equal to the length of 14 symbols, and when the length of the backhaul uplink subframe is equal to the length of 12 symbols.

In FIGS. 19 and 20, the last symbol of the backhaul uplink subframe indicates that the backhaul uplink physical data channel is transmitted. However, according to the backhaul uplink subframe, the last symbol of the backhaul uplink subframe may be transmitted as a backhaul uplink channel measurement reference signal.

19A to 19E show preferred embodiments of a frame structure in the case where two backhaul uplink demodulation reference signals 810 and 820 are present in a backhaul uplink subframe including 14 symbols .

The backhaul uplink subframe structure (a) of FIG. 19 is a case where the guard interval is negligibly small. The first backhaul uplink demodulation reference signal 810 is located in the fourth symbol, and the second backhaul uplink demodulation reference signal 820 ) Is located in the 11th symbol. Six symbols are located between the two backhaul uplink demodulation reference signals.

The backhaul uplink subframe structure (b) of FIG. 19 is a case where the preceding guard interval 401 and the following guard interval 402 are located before and after the backhaul uplink signal interval, and actually transmits signals in one subframe There are 13 symbols. According to the subframe structure of FIG. 19 (b), the first backhaul uplink demodulation reference signal 810 is located in the third symbol, the second backhaul uplink demodulation reference signal 820 is located in the tenth symbol, Six symbols are located between the backhaul uplink demodulation reference signals.

In the backhaul uplink subframe structure (c) of FIG. 19, the leading guard interval 401 and the trailing guard interval 402 are positioned before and after the backhaul uplink signal interval, respectively. Symbols for actually transmitting signals in one subframe are All 13 symbols. In the subframe structure of FIG. 19 (c), the first backhaul uplink demodulation reference signal 810 is located in the fourth symbol and the second backhaul uplink demodulation reference signal 820 is located in the eleventh symbol.

In the backhaul uplink subframe structure (d) of FIG. 19, the leading guard interval 401 and the trailing guard interval 402 are located before the backhaul uplink signal interval. However, in this case, ) Are longer, the number of symbols that actually transmit signals in one subframe is twelve. In the subframe structure of FIG. 19 (d), the first backhaul uplink demodulation reference signal 810 is located in the third symbol and the second backhaul uplink demodulation reference signal 820 is located in the tenth symbol.

The backhaul uplink subframe structure (e) of FIG. 19 has a guard interval of the same length as in the case of (d), and 12 symbols are actually transmitted in one subframe. 19 (e), the first backhaul uplink demodulation reference signal 810 is located in the second symbol and the second backhaul uplink demodulation reference signal 820 is located in the ninth symbol.

In the backhaul uplink subframe structure according to an embodiment of the present invention, two backhaul uplink demodulation reference signals are arranged in one backhaul uplink subframe, The reference signal is located between (one half of the maximum number of symbols that a backhaul uplink subframe can contain - 1) symbols. That is, in the case of FIG. 19, a maximum of 14 symbols may exist in one backhaul uplink subframe, and the number obtained by subtracting 1 from 7, which is half of 14, that is, 6 symbols, 810 and the second backhaul uplink demodulation reference signal 820.

20 (a) to 20 (e) show preferred embodiments of a frame structure in the case where two backhaul uplink demodulation reference signals exist in a backhaul uplink subframe including 12 symbols.

The backhaul uplink subframe structure (a) of FIG. 20 is a case where the guard interval is negligibly small. The first backhaul uplink demodulation reference signal 810 is located in the third symbol, the second backhaul uplink demodulation reference signal 820 ) Is located in the ninth symbol. Five symbols are located between the two backhaul uplink demodulation reference signals.

The backhaul uplink subframe structure (b) of FIG. 20 is a case where the preceding guard interval 401 and the backward guard interval 402 are located before the backhaul uplink signal interval, respectively, and actually transmits signals in one subframe The symbols are all 11 symbols. 20B, the first backhaul uplink demodulation reference signal 810 is located in the second symbol, the second backhaul uplink demodulation reference signal 820 is located in the eighth symbol, Five symbols are located between the backhaul uplink demodulation reference signals.

The backhaul uplink subframe structure (c) of FIG. 20 has a leading and trailing guard interval of the same length as the case of 20 (b). According to the subframe structure of FIG. 20 (c), the first backhaul uplink demodulation reference signal 810 is located in the third symbol and the second backhaul uplink demodulation reference signal 820 is located in the ninth symbol.

In the backhaul uplink subframe structure (d) of FIG. 20, the guard interval is located before the backhaul uplink signal interval. In this case, however, the length of the guard interval 402 is longer than the above- The number of symbols actually transmitting signals in the frame is 10. In the subframe structure of FIG. 20 (d), the first backhaul uplink demodulation reference signal 810 is located in the second symbol and the second backhaul uplink demodulation reference signal 820 is located in the eighth symbol.

The backhaul uplink subframe structure (e) of FIG. 20 has guard intervals 401 and 402 of the same length as in the case of (d), and all the symbols actually transmitting signals in one subframe are 10 . 20 (e), the first backhaul uplink demodulation reference signal 401 is located in the first symbol and the second backhaul uplink demodulation reference signal 402 is located in the seventh symbol.

20, the same principle as in FIG. 19 is applied. That is, in the backhaul uplink subframe structure according to an embodiment of the present invention, two backhaul uplink demodulation reference signals are arranged in one backhaul uplink subframe, and these two demodulation reference signals (one backhaul uplink Half of the maximum number of symbols that can be included in the subframe - 1) symbols. That is, in the case of FIG. 20, a maximum of 12 symbols may exist in one backhaul uplink subframe, and the number obtained by subtracting 1 from 6, which is half of 12, that is, 5 symbols is transmitted as a first backhaul uplink demodulation reference signal 810 and the second backhaul uplink demodulation reference signal 820.

FIGS. 21 and 22 show the arrangement of the backhaul uplink demodulation reference signal in the backhaul uplink subframe when there is a total of one backhaul uplink demodulation reference signal in the backhaul uplink subframe.

FIG. 21 shows preferred embodiments of a frame structure in which one backhaul uplink demodulation reference signal 1000 is placed in a backhaul uplink subframe having 14 symbols.

21 (a) and 21 (b) show a case where the guard interval is negligibly small, and FIGS. 21 (c) to 21 (h) show a case in which the guard interval 401 and the guard interval (402) is positioned. As can be seen from FIG. 21, the length of the guard interval may vary depending on various factors, and the length of the guard interval shown in FIG. 21 is only an embodiment.

In FIG. 21, the last symbol of the backhaul uplink subframe assumes that the backhaul uplink physical data channel is transmitted. However, according to the backhaul uplink subframe, the last symbol of the backhaul uplink subframe may be transmitted as a backhaul uplink channel measurement reference signal.

21A and 21B, since the guard interval is negligibly small, the backhaul uplink signal interval in which the actual signal is transmitted is composed of a total of 14 symbols. (a) shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the seventh symbol, and (b) shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the eighth symbol.

21 (c) and 21 (e) show the case where the guard interval is located before and after the backhaul uplink signal interval, respectively, and the backhaul uplink signal The interval consists of a total of 13 symbols. (d) shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the seventh symbol, (e) a case where the backhaul uplink demodulation reference signal 1000 is arranged in the sixth symbol, Shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the eighth symbol.

21 (f) to 21 (h) show a case where the trailing guard interval 402 is longer than that in FIGS. 21 (c) to 21 (e) Symbol. (g) shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the 6th symbol, (h) a case where the backhaul uplink demodulation reference signal 1000 is arranged in the 5th symbol, Shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the seventh symbol.

The uplink transmission method according to an exemplary embodiment of the present invention shown in FIG. 21 configures an uplink frame in which only one backhaul uplink demodulation reference signal is arranged in one backhaul uplink subframe. In this case, the backhaul uplink demodulation reference signal is (1000), the number of symbols preceding in time with respect to the backhaul uplink demodulation reference signal in one backhaul uplink subframe and the number of symbols trailing behind in time And a difference is not exceeded by 3.

FIG. 22 shows preferred embodiments of a frame structure when one backhaul uplink demodulation reference signal is placed in a backhaul uplink subframe having 12 symbols.

22 (a) and 22 (b) show a case where the guard interval is negligibly small, and FIGS. 22 (c) to (h) show a case in which the leading guard interval 401 and the trailing guard interval (402) is positioned. As can be seen from FIG. 22, the length of the guard interval may vary depending on various factors, and the length of the guard interval shown in FIG. 22 is only the embodiments.

In FIG. 22, the last symbol of the backhaul uplink subframe assumes that the backhaul uplink physical data channel is transmitted. However, according to the backhaul uplink subframe, the last symbol of the backhaul uplink subframe may be transmitted as a backhaul uplink channel measurement reference signal.

22 (a) and 22 (b), since the guard interval is negligibly small, the backhaul uplink signal interval in which the actual signal is transmitted is composed of 12 symbols in total. (a) shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the sixth symbol, and (b) shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the seventh symbol.

22 (c) to 22 (e) show a case where the guard interval is located before and after the backhaul uplink signal interval, and the backhaul uplink signal interval in which the signal is actually transmitted is 11 symbols in total. (d) shows a case in which the backhaul uplink demodulation reference signal 1000 is arranged in the 6th symbol, (e) a case in which the backhaul uplink demodulation reference signal 1000 is arranged in the 5th symbol, Shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the seventh symbol.

22 (f) to 22 (h) show a case where the trailing guard interval 402 is longer than the case of FIGS. 22 (c) to 22 (e) Symbol. (f) shows the case where the backhaul uplink demodulation reference signal 1000 is arranged in the fourth symbol, (g) the case where the backhaul uplink demodulation reference signal 1000 is arranged in the fifth symbol, Shows a case where the backhaul uplink demodulation reference signal 1000 is arranged in the sixth symbol.

In summary, an uplink transmission method according to a preferred embodiment of the present invention shown in FIG. 22 constitutes an uplink frame in which only one backhaul uplink demodulation reference signal is arranged in one backhaul uplink subframe. At this time, the backhaul uplink demodulation reference signal 1000 includes a number of symbols preceding in time with respect to the backhaul uplink demodulation reference signal in one backhaul uplink subframe, and a number of symbols trailing behind in time It can be confirmed that the difference is located at a position not exceeding 3.

Hereinafter, backhaul downlink transmission according to another aspect of the present invention will be described.

As described above with reference to FIG. 2, the base station and the relay exchange backhaul downlink signals. The backhaul downlink signal may include a backhaul downlink physical data channel, a backhaul downlink physical control channel, a backhaul downlink reference signal, and may further include a channel or signal other than the explicitly mentioned channel or signal .

The start position of the backhaul downlink signal is determined by the number of symbols to which the base station access downlink physical control channel is transmitted among the base station access downlink signals, the number of symbols through which the relay access downlink physical control channel is transmitted among the relay access downlink signals, The propagation delay between the relays, the transition timing from the transmission to the reception of the relay, the timing configuration of the relay access downlink subframe, and the like. The end position of the backhaul downlink signal may vary depending on, for example, a propagation delay between a base station and a relay, a transition timing from reception of a relay to a transmission, and a timing configuration of a relay access downlink subframe.

In order to determine the start position of the backhaul downlink signal, the relay may transmit the number of symbols to which the relay access downlink physical control channel is transmitted to the base station. Alternatively, the base station may transmit the number of symbols to which the relay access physical downlink control channel is transmitted to the relay. The relay transmits the relay access downlink physical control channel according to the information received from the base station.

One or a plurality of backhaul downlink physical control channels are transmitted in the backhaul downlink physical control channel region, where the region refers to a combination of a time domain, a frequency domain, a spatial domain, a code domain, and the like. The start position of the time domain of the backhaul downlink physical control channel region may be predefined and may not signal the start position information or the start position information through the upper layer signaling (which may be RRC signaling in case of 3GPP) Lt; / RTI >

Here, the start position information of the time domain of the backhaul downlink physical control channel region means a symbol index in which the time domain of the backhaul downlink physical control channel region starts in the base station access downlink subframe. The end position of the time domain of the backhaul downlink physical control channel region may be predefined and may not signal the end position information or the end position information may be transmitted through upper layer signaling (which may be RRC signaling in case of 3GPP) Lt; / RTI > In addition, the end position information of the time domain of the backhaul downlink physical control channel region means a symbol index in which the time domain of the backhaul downlink physical control channel region ends in the base station access downlink subframe.

The location of the frequency domain of the backhaul downlink physical control channel region may transmit frequency domain location information through higher layer signaling (which may be RRC signaling in the case of 3GPP). Here, the frequency-domain location information of the backhaul downlink physical control channel region indicates the position of the frequency domain in which the backhaul downlink physical control channel is transmitted in the system bandwidth, and may be notified in units of subcarriers or aggregate units of subcarriers.

The start position of the time domain of the backhaul downlink physical data channel may be predefined and may not signal the start position information or the start position information may be transmitted through the upper layer signaling (which may be RRC signaling in case of 3GPP) Or may transmit the start position information through the backhaul downlink physical control channel.

Here, the start position information of the time domain of the backhaul downlink physical data channel means a symbol index in which the time domain of the backhaul downlink physical data channel starts in the base station access downlink subframe. The symbol index may be expressed as an absolute value or a relative value based on a specific symbol index in a base station access downlink subframe. Also, the specific symbol may be a symbol that starts in the time domain of the backhaul downlink physical control channel region.

The end position of the time domain of the backhaul downlink physical data channel may be predefined and may not signal the end position information or the end position information may be transmitted through upper layer signaling (which may be RRC signaling in case of 3GPP) .

Here, the end position information of the time domain of the backhaul downlink physical data channel means a symbol index in which the time domain of the backhaul downlink physical data channel ends in the base station access downlink subframe. The symbol index may be expressed as an absolute value or a relative value based on a specific symbol index in a base station access downlink subframe. Here, the specific symbol may be a symbol in which the time domain of the backhaul downlink physical control channel region ends.

The position of the frequency domain of the backhaul downlink physical data channel can transmit the frequency domain location information through the backhaul downlink physical control channel. Here, the frequency-domain location information of the backhaul downlink physical data channel indicates the position of the frequency domain in which the backhaul downlink physical control channel is transmitted in the system bandwidth, and may be notified in units of subcarriers or aggregate units of subcarriers. The frequency region of the backhaul downlink physical data channel may include a frequency region of the backhaul downlink physical control channel indicating the backhaul downlink physical data channel.

In the following, we will discuss the topic related to the information transmitted over the backhaul link between the base station and the relay as discussed above, in particular the relay system information transmission through the backhaul link between the base station and the relay.

In a situation where the relay operates in the terminal mode of the relay, the relay can receive the base station cell system information transmitted by the base station to which the relay belongs to a terminal and a relay belonging to the base station cell through the downlink have. Relay system information common to the relays in the terminal mode of the relay is transmitted through dedicated signaling for each relay (for example, RRC signaling in case of 3GPP system).

However, in a state where the relay operates in the base station mode of the relay, since the relay transmits data to the relay terminal, it can not receive the base station access downlink and may not receive the relay system information.

Herein, the relay system information refers to information that can be commonly applied to all relays that are interworked with the base station among the information transmitted by the base station to the relay when the base station and the at least one relay are interlocked. One example of the relay system information is information on the backhaul downlink physical control channel region. Information about the backhaul downlink physical control channel region may include time information of the backhaul downlink physical control channel and location information of frequency resources. The location information of the time resource may be represented by an index of a start symbol and an end symbol. The location information of the frequency resource may be represented by an index of a start frequency resource and an end frequency resource (in the case of 3GPP, a PRB index), or may be expressed in a bitmap format. When expressed in a bitmap format, it means that only the frequency resource through which the backhaul downlink physical control channel is transmitted among all the frequency resources is expressed as 1.

The relay system information may also include some system information of the base station cell to which the base station to which the relay belongs transmits to terminals and relays belonging to the base station cell.

It has been previously mentioned that relay system information may not be received through the base station access downlink when the relay operates in the base station mode of the relay. According to the present invention, relay system information can be transmitted through a backhaul downlink in a state where the relay operates in a base station mode of the relay.

In one embodiment of the present invention, relay system information is transmitted through a backhaul downlink physical control channel among resources allocated to a backhaul downlink, and is referred to as a relay common backhaul downlink physical control channel for convenience. The relay common backhaul downlink physical control channel may include information on time, frequency position, modulation, and encoding of the backhaul downlink physical data channel through which relay system information is transmitted.

Since the relay common backhaul downlink physical control channel is information on a plurality of relays, a plurality of relays must be capable of demodulating. For this purpose, it is possible to mask transmission error check data, for example, CRC (Cyclic Redundancy Check) of the relay common backhaul downlink physical control channel with a relay common identifier. For example, a Relay System Information-Radio Network Temporary Identifier (RSI-RNTI) can be used as the relay common identifier.

23 shows a transmission cycle of relay system information according to an embodiment of the present invention.

The relay system information according to the present invention can be changed to a fixed period Tm, as shown in Fig. 23, and is not changed within one period. For convenience, this period is referred to as a relay system information modification period. The relay system information change period can be set, for example, as at least one radio frame or at least one subframe. The length information of the relay system change period can be transmitted in the relay system information.

A relay public system backhaul downlink physical control channel may include a relay system information in a next change period, and a relay public system backhaul physical control channel may include a relay system information And the relay system information change notification may be included at least once within one change period Tm. The relay system information change notification can be implemented, for example, in the form of a bit indicating whether the relay system information is changed. If the corresponding bit is 1, the relay system information is changed in the next change cycle. If the bit is 0, it means that there is no change in the relay system information in the next change period.

Next, how subframes used for the BS access downlink and the backhaul uplink to which the backhaul downlink signals discussed above are transmitted will be described.

The base station may allocate a base station access downlink subframe in which one or a plurality of backhaul downlink signals are transmitted to the relay. The base station access downlink subframe allocation information may be transmitted in a bitmap format through upper layer signaling (RRC signaling in case of 3GPP). The bitmap format is used for a base station access downlink frame or a backhaul downlink signal for a corresponding base station access downlink subframe using 0 or 1 for each of base station access downlink subframes constituting a plurality of base station access downlink frames Is transmitted. For example, if it is 1, the backhaul downlink signal is transmitted to the corresponding base station access downlink subframe, and if it is 0, the backhaul downlink signal is not transmitted to the corresponding base station access downlink subframe.

In addition, the base station access downlink subframe allocation information may include at least one of a transmission period and a position information format of a base station access downlink subframe in a base station access downlink frame corresponding to each transmission period, RRC signaling).

The base station may transmit the base station access downlink subframe allocation information in which the same backhaul downlink signal is transmitted to all the relays transmitting and receiving the backhaul downlink signal with the base station, or may transmit the base station access downlink subframe allocation information differently for each relay. In addition, the base station may divide the relay for transmitting and receiving the backhaul downlink signal with the base station into a plurality of relay groups, and may transmit the base station access downlink subframe allocation information in which different backhaul downlink signals are transmitted for each relay group. Here, the relay group may be composed of one or a plurality of relays, and the relays belonging to the specific relay group are received the base station access downlink subframe allocation information in which the same backhaul downlink signal is transmitted.

In addition, the base station may allocate one or more backhaul uplink subframes to the relay. The backhaul uplink subframe allocation information may be transmitted in a bitmap format through upper layer signaling (RRC signaling in case of 3GPP). The bitmap format indicates whether the backhaul uplink subframe is allocated to the backhaul uplink subframe using 0 or 1 for each backhaul uplink subframe constituting one backhaul uplink frame or a plurality of backhaul uplink frames. For example, if 1, the backhaul uplink signal is transmitted to the corresponding backhaul uplink subframe, and if 0, the backhaul uplink signal is not transmitted to the corresponding backhaul uplink subframe. In addition, the backhaul uplink subframe allocation information includes upper layer signaling (RRC signaling in case of 3GPP) as a position information format of a backhaul uplink subframe in a backhaul uplink frame corresponding to one or a plurality of transmission periods and each transmission period Lt; / RTI >

The base station may transmit the same backhaul uplink subframe allocation information to all the relays that transmit and receive the backhaul uplink signal to the base station, or may transmit the same backhaul uplink subframe allocation information differently for each relay. Further, the base station may divide the relay, which transmits and receives the backhaul uplink signal with itself, into a plurality of relay groups, and may transmit different backhaul uplink subframe allocation information for each relay group. Here, the relay group is composed of one or a plurality of relays, and relays belonging to a specific relay group receive the same backhaul uplink subframe allocation information from the base station.

Hereinafter, the validity period information for the backhaul downlink / uplink physical data channel will be discussed.

The base station transmits resource allocation information for the backhaul downlink physical data channel to the relay. The resource allocation information includes information such as a position on physical resources such as time, frequency, and space of a backhaul downlink physical data channel, a modulation scheme, a Hybrid Automatic Repeat reQuest information, and the like. When a base station transmits a backhaul downlink physical data channel to a relay, it can transmit resource allocation information for each backhaul downlink physical data channel. Also, the base station may transmit only one resource allocation information for a plurality of backhaul downlink physical data channels to the relay. At this time, it is possible to include the valid period information in the resource allocation information. Here, the valid period information indicates how many backhaul downlink physical data channels the resource allocation information including the valid period information is applied to. For example, when the valid period information indicates n, the resource allocation information including the valid period information is applied to the n backhaul downlink physical data channels in the same manner. Here, the backhaul downlink physical data channel to which the valid period information is applied may include HARQ retransmission or only initial transmission except HARQ retransmission.

In addition, the base station transmits resource allocation information for the backhaul uplink physical data channel to the relay. The resource allocation information includes information on the physical resources such as time, frequency, and space of the backhaul uplink physical data channel, modulation scheme, HARQ Automatic Repeat reQuest) information, and the like. When a base station transmits a backhaul uplink physical data channel to a relay, it can transmit resource allocation information for each backhaul uplink physical data channel. Also, the base station may transmit only one resource allocation information for a plurality of backhaul uplink physical data channels to the relay. At this time, validity period information may be included in the resource allocation information. This valid period information indicates how many backhaul uplink physical data channels the resource allocation information including the valid period information is applied to. For example, when the valid period information indicates n, the resource allocation information including the valid period information is similarly applied to n backhaul uplink physical data channels.

Hereinafter, an ACK / NACK mechanism that can be applied to a backhaul link with respect to a radio environment of a backhaul link between a base station and a relay will be discussed.

When the relay receives the backhaul downlink physical data channel, the relay transmits demodulation success information, i.e., ACK or NACK, on the backhaul uplink according to whether the backhaul downlink physical data channel is successfully demodulated. When one backhaul downlink physical data channel is composed of a plurality of codewords, demodulation success or failure information may be transmitted for each codeword. The plurality of demodulation success or failure information may be transmitted through one or a plurality of modulation symbols.

The resources for relaying demodulation success information can be connected one-to-one with the transmitted resources of the backhaul downlink physical control channel including the allocation information of the backhaul downlink physical data channel. In this case, when the transmitted resource of the backhaul downlink physical control channel is changed, the resource to which the demodulation success or failure information is transmitted is also changed. Here, the resource is composed of a combination of a time domain resource, a frequency domain resource, a code domain resource, and a cyclic shift domain resource.

Also, the resource to which the demodulation success information is transmitted may be independent of the transmitted resource of the backhaul downlink physical control channel. In this case, the base station can inform the relay of resources through which demodulation success / failure information is transmitted through higher layer signaling (which may be RRC signaling in case of 3GPP), and the relay transmits demodulation success / failure information to the resource.

There may also be two factors that determine the resources to which the demodulation success or failure is transmitted. That is, one element is one-to-one connected to the transmitted resource of the backhaul downlink physical control channel, and the other element is independent of the transmitted resource of the backhaul downlink physical control channel.

BACKGROUND ART [0002] Recently, a method of using a multiple input multiple output (MIMO) scheme for downlink or uplink between a base station and a mobile station has been actively discussed. There are also studies on MIMO technology in which multiple radio paths occur, such as MIMO 8x8 or 4x8 MIMO. On the other hand, in the case where the high-order MIMO technique is applied, a plurality of codewords may be used (up to a maximum of two codewords may be supported), and ACK / NACK information may be separately configured for each codeword send.

Regarding the relays, the relays are generally located at a high place such as the top of a building. Therefore, the radio environment between the base station and the relay is often a line of sight (LOS). In case of applying MIMO technology in this LOS environment, correlation between transmission paths is likely to occur. Therefore, in the backhaul transmission method according to an embodiment of the present invention, it is unnecessary to separately transmit response information, i.e., ACK / NACK information for each codeword for the backhaul link between the relay and the base station, ACK / NACK information), i.e., bundling and transmitting the ACK / NACK information. As a concrete method of implementing this, for example, there is a method of ANDing each success or failure of transmission for each codeword. In this case, only when all the transmissions for a plurality of codewords are successful, an ACK Information is transmitted, and in the remaining cases, NACK information is transmitted in all cases. If two codewords are used and two bits are required for ACK / NACK transmission in the backhaul link, the present invention advantageously increases the transmission efficiency because only one bit is used.

For example, the backhaul uplink signal is transmitted in a single backhaul uplink subframe, and the bundle of ACK / NACK information is transmitted to one backhaul uplink subframe, As shown in Fig. Bundling of ACK / NACK information may be applied to a plurality of backhaul uplink subframes. When the backhaul uplink physical data composed of a plurality of codewords is transmitted in each backhaul uplink subframe, for each of the first codewords of each backhaul uplink subframe and for the second codewords, ACK You can also bundle / NACK.

The base station may inform the relay whether or not to bundle the ACK / NACK information. When the base station applies bundling of ACK / NACK information to the relay, the relay bundles ACK / NACK information for all codewords of the backhaul downlink physical data channel and transmits the ACK / NACK information to the base station. And transmits ACK / NACK information for all codewords to the relay. When the base station does not apply bundling of ACK / NACK information to the relay, the relay transmits ACK / NACK information to the base station for each codeword of the backhaul downlink physical data channel, and the base station transmits the ACK / NACK information to the backhaul uplink physical data channel And transmits ACK / NACK information for each codeword in the relay to the relay.

According to an embodiment of the present invention, when transmitting ACK / NACK information between a base station and a relay, ACK / NACK information for all codewords is bundled by transmitting a basic transmission mode in a bundling mode In the exceptional case where the wireless environment between the base station and the relay changes rapidly, the bundling mode is released and the normal mode can be applied.

Claims (20)

A method for downlink transmission in a mobile communication network including a relay,
Transmitting a backhaul downlink signal according to a backhaul downlink frame structure and a backhaul downlink timing determined in consideration of at least one of a transmission / reception switching time and a signal transmission time of a relay; Wow
Wherein the relay receives the backhaul downlink signal according to the frame configuration and timing of the backhaul downlink. The method according to claim 1,
The step of transmitting the backhaul downlink signal includes:
The base station includes a backhaul which includes symbols starting from the following symbol to the last symbol except for symbols from the first symbol of the base station access downlink subframe (the number of symbols to which the relay access downlink control channel is transmitted + 1) Wherein the backhaul downlink signal is transmitted using symbols for transmitting a downlink signal. The method of claim 2,
The starting point of the relay access downlink sub-frame with respect to the timing of the backhaul downlink,
Wherein the first symbol of the base station access downlink sub-frame is set backward by a length of a downlink posterior guard interval from a point at which the first symbol of the base station access downlink sub-frame starts to be received by the relay. The method according to claim 1,
The step of transmitting the backhaul downlink signal includes:
The number of symbols (number of symbols to which the relay access downlink control channel is transmitted + 1) is excluded from the last symbol in the time reversely to the first symbol of the base station access downlink subframe, Wherein the backhaul downlink signal is transmitted using symbols for transmitting a link signal. The method of claim 4,
The starting point of the relay access downlink sub-frame with respect to the timing of the backhaul downlink,
Is set in advance by a value obtained by summing the time interval in which the control information for the relay access downlink is transmitted and the length of the downlink preceding guard interval from the time when the first symbol of the base station access downlink subframe starts to be received by the relay And a downlink transmission method. The method according to claim 1,
The step of transmitting the backhaul downlink signal includes:
From the first symbol of the base station access downlink subframe to the first symbol except for the number of symbols to which the relay access downlink control channel is transmitted, excluding the last symbol, The backhaul downlink signal is transmitted using the symbols for transmitting the backhaul downlink signal,
Wherein the start symbol and the end symbol of the symbols for transmitting the backhaul downlink signal differ according to the length of signal transmission time of the backhaul downlink. The method of claim 6,
Wherein the start point of the relay access downlink subframe related to the timing of the backhaul downlink is set according to the start time of the base station access downlink subframe. The method of claim 7,
The transmission time point of the relay access downlink subframe is set to be half the time indicated by the timing advance information transmitted from the base station to the relay from the time when the first symbol of the base station access downlink subframe starts to be received by the relay, Wherein a start point of a relay access downlink subframe is set to a start point of a base station access downlink subframe. The method according to claim 1,
The step of transmitting the backhaul downlink signal includes:
From the first symbol of the base station access downlink subframe, the symbols for the number of symbols to which the relay access downlink control channel is transmitted are excluded, and the symbols for transmitting the backhaul downlink signal starting from the following symbol to the last symbol are used A downlink transmission method for transmitting a backhaul downlink signal. The method of claim 9,
The starting point of the relay access downlink sub-frame with respect to the timing of the backhaul downlink,
Wherein the first symbol of the base station access downlink sub-frame is set to a time point at which the first symbol of the base station access downlink sub-frame starts to be received by the relay. A method for uplink transmission in a mobile communication network including a relay,
Transmitting a backhaul uplink signal according to a frame structure and timing of a backhaul uplink determined in consideration of at least one of relay transmission / reception switching time and signal transmission time; And
And a base station receiving the backhaul uplink signal according to the frame structure and timing of the backhaul uplink. The method of claim 11,
Wherein the step of transmitting the backhaul uplink signal comprises:
Wherein the relay transmits a backhaul uplink signal using symbols for transmitting a backhaul uplink signal including a first symbol starting from a second symbol of a backhaul uplink subframe to a last symbol. The method of claim 12,
The starting point of the backhaul uplink sub-frame with respect to the timing of the backhaul uplink,
Wherein the relay is set backward by an uplink guard interval at a time of transmitting a base station access uplink signal in a terminal mode of a relay. The method of claim 11,
Wherein the step of transmitting the backhaul uplink signal comprises:
Wherein a backhaul uplink signal is transmitted using symbols for transmitting a backhaul uplink signal including a first symbol from a first symbol of a backhaul uplink subframe to a second symbol from a last symbol. 15. The method of claim 14,
The starting point of the backhaul uplink sub-frame with respect to the timing of the backhaul uplink,
Wherein the relay is set up by an uplink guard interval at the time of transmitting the base station access uplink signal in the terminal mode of the relay. The method of claim 11,
Wherein the step of transmitting the backhaul uplink signal comprises:
The backhaul uplink signal is transmitted using the symbols for transmitting the backhaul uplink signal having the maximum number of symbols starting from the second symbol of the backhaul uplink subframe to the last symbol,
Wherein the start symbol and the end symbol of the symbols for transmitting the backhaul uplink signal are variable according to at least one of a length of the signal transmission time of the backhaul uplink and a transmission / reception switching time of the relay. 18. The method of claim 16,
The starting point of the backhaul uplink sub-frame with respect to the timing of the backhaul uplink,
And the start time of the uplink sub-frame is set to be equal to the start time of the base station access uplink sub-frame. 18. The method of claim 17,
The starting point of the backhaul uplink sub-frame with respect to the timing of the backhaul uplink,
Wherein the relay is set to a half of a time indicated by the timing advance information transmitted from the base station to the relay at the time of transmitting the base station access uplink signal in the terminal mode of the relay. The method of claim 11,
Wherein the step of transmitting the backhaul uplink signal comprises:
Wherein the backhaul uplink signal is transmitted using symbols for transmitting a backhaul uplink signal including symbols starting from a first symbol of a backhaul uplink subframe to a last symbol. The method of claim 19,
The starting point of the backhaul uplink sub-frame with respect to the timing of the backhaul uplink,
And the relay is set to a time point at which the base station access uplink signal is transmitted in the terminal mode of the relay.

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